Mouth-detecting teeth-whitening device

ABSTRACT

Devices for whitening teeth that include at least one sensor that senses whether the device is in the mouth of the user, an electro-magnetic field (EMF) array, or an accelerometer. The sensor(s) or EMF array may enable operation of the device only when the device is in the mouth, turn on the device or a light when placed in the mouth, turn off the device when the device is removed from the mouth, or not allow the device to operate when the device is not in the mouth. A timer may turn off the device. The time may be adjustable, automatically adjusted (e.g., by the device), or adjusted based on color or shade of the teeth. Some embodiments have multiple sensors or EMF arrays or include a wakeup device or accelerometer. The accelerometer may wake up the device when the device is shaken.

RELATED PATENT APPLICATIONS

This patent application is a non-provisional patent application of, andclaims priority to: U.S. provisional patent application numbers:

62/687,632, filed Jun. 20, 2018, TEETH WHITENING DEVICE;

62/750,549, filed Oct. 25, 2018, TEETH WHITENING WITH EXTERNAL ORCONTROLLED LIGHT SOURCE;

62/750,601, filed Oct. 25, 2018, COLOR OR SHADE SENSING TEETH-WHITENINGDEVICE;

62/750,630, filed Oct. 25, 2018, SELF-DISINFECTING TEETH-WHITENINGDEVICE;

62/750,652, filed Oct. 25, 2018, MOUTH-DETECTING TEETH-WHITENING DEVICE;and

62/750,674, filed Oct. 25, 2018, CONNECTED TEETH-WHITENING DEVICE.

The contents of these priority provisional patent applications areincorporated herein by reference. If there are any conflicts orinconsistencies between this patent application and the incorporatedprovisional patent applications, however, this patent applicationgoverns herein.

FIELD OF THE INVENTION

Various embodiments of this invention relate to devices and methods forwhitening teeth including electronic devices and devices and methodsthat use a source of light to whiten teeth.

BACKGROUND OF THE INVENTION

In the past, various devices and methods have been used to whiten teethincluding electronic devices that use light to whiten the teeth. Variousproblems encountered in prior technology are described herein. Needs orpotential for benefit exist for better devices, including, electronicdevices, and methods that whiten teeth. Room for improvement exists overthe prior art in these and other areas that may be apparent to a personof skill in the art having studied this document.

SUMMARY OF PARTICULAR EMBODIMENTS OF THE INVENTION

This invention provides, among other things, devices, methods, andsystems that whiten teeth, including electronic devices and devices andmethods that use light to whiten teeth. Various embodiments provide, forexample, as an object or benefit, that they partially or fully addressor satisfy one or more of the needs, potential areas for benefit, oropportunities for improvement described herein or known in the art, asexamples. Certain embodiments provide, for example, as objects orbenefits, for instance, that they whiten teeth, for example, usinglight. Various embodiments are better than prior art alternatives in oneor more ways, for instance, as described herein. Various embodiments aredescribed herein or would be apparent to a person of ordinary skill inthe art having studied this document.

Various embodiments are or include, for example, devices for whiteningteeth of a user. Specific embodiments include, for instance, a lightsource and a light delivery mechanism, for example, that delivers lightfrom the light source to the user's teeth. In some embodiments, forexample, when the device is being used to whiten the teeth of the user,the light source is located outside the mouth of the user. Further, incertain embodiments, when the device is being used to whiten the teethof the user, the light delivery mechanism is located inside the mouth ofthe user. Further still, in particular embodiments, the light deliverymechanism is or includes a reflector. Even further, some embodimentsinclude a pulse width modulation circuit, for example, that drives thelight source. Still further, in particular embodiments, the light sourceincludes multiple LEDs, multiple independently-controlled light sources,or both, as examples. Even further still, in certain embodimentsintensity of the light source is controlled, the device is controlledwirelessly using a separate electronic device, the device is controlledusing hand gestures, the device includes a gesture sensor that senseshand gestures, or a combination thereof, as examples. Moreover, inparticular embodiments, the device for whitening teeth includes twoantennas, an infrared receiver, or both (e.g., to detect hand gestures).

Numerous specific embodiments of a device for whitening teeth of a userinclude both a light source and a reflector. Further, in a number ofembodiments, when the device is being used to whiten the teeth of theuser, the light source is located outside the mouth of the user and thereflector is located inside the mouth of the user. Still further,various specific embodiments of a device for whitening teeth of a userinclude a light source and a pulse width modulation circuit, forinstance, that drives the light source. Even further, in particularembodiments, the light source includes multiple light sources, forinstance, that are each independently controlled, for example, by thepulse width modulation circuit. Even further still, in certainembodiments, the device is controlled wirelessly using a separateelectronic device, using hand gestures, or both, as examples.

For many specific embodiments of devices for whitening the teeth of auser, the device includes a color sensor, for example, that detectscolor of the teeth of the user. Further, in a number of embodiments, thedevice controls a teeth-whitening process, for instance, using the colorof the teeth of the user, the device for whitening teeth includes aprocessor, for example, that controls the teeth-whitening process, forinstance, using the color of the teeth of the user, or a combinationthereof. Still further, in various embodiments, the device includes alight source, for example, that emits light that is reflected by theteeth, and used, for instance, by the device, to detect the color of theteeth of the user. Moreover, in various embodiments, the device includesa light source, for example, that shines light on the teeth, forinstance, to whiten the teeth. Even further, in some embodiments, thedevice uses the color of the teeth to determine, for example, intensityof light to shine onto the teeth. Further still, in particularembodiments, the device includes cool light source elements, warm lightsource elements, or both. Even further still, in certain embodiments,the device includes multiple color sensors, and, in particularembodiments, different color sensors of the multiple color sensors sensecolor of the teeth of the user in different areas of the mouth of theuser. Further, in other embodiments, shade sensors are used in additionto, or instead of, color sensors, and shade of the teeth is used.

In some embodiments, the device uses a learning algorithm, for example,to determine a teeth-whitening process, for instance, using the color ofthe teeth of the user. Further, in certain embodiments, the device forwhitening teeth includes multiple independently-controlled lightsources. Still further, in particular embodiments, the device forwhitening teeth includes a light source and a reflector and (e.g., whenthe device is being used to whiten the teeth of the user) the lightsource is located outside the mouth of the user, the reflector islocated inside the mouth of the user, or both. Further still, in variousembodiments, the device for whitening teeth includes a pulse widthmodulation circuit, the device is controlled wirelessly (e.g., using aseparate electronic device), the device includes a gesture sensor (e.g.,that senses hand gestures used to control the device), or a combinationthereof, as examples.

In many specific embodiments of a device for whitening teeth of a user,the device collects data from light that is reflected from the teeth andcontrols a teeth-whitening process using the data. In a number ofembodiments, for example, the data includes color of the teeth and thedevice uses the color of the teeth to control the teeth-whiteningprocess. Further, in some embodiments, for example, the data includesshade of the teeth and the device uses the shade of the teeth to controlthe teeth-whitening process. Further still, in many embodiments, theteeth-whitening process includes shining light on the teeth to whitenthe teeth. Still further, in various embodiments, a device for whiteningteeth of a user includes (e.g., color, shade, or both) sensors, forexample, used to analyze reflected light from a target surface of theteeth, for instance, to recommend a whitening treatment for the teeth.Even further, in a number of embodiments, the device produces the lightthat becomes the reflected light when reflected by the target surface ofthe teeth. Even further still, in some embodiments, the device includesa processor that controls the device.

Various specific embodiments of a device for whitening teeth include amouth piece and an ultraviolet light source. In many embodiments, forexample, the ultraviolet light source sterilizes at least a portion ofthe device. In particular, in a number of embodiments, the ultravioletlight source sterilizes at least a portion of the mouth piece. Further,in various embodiments, the ultraviolet light source operates only whenthe mouth piece is not in the user's mouth, when the mouth piece ischarging, or both. In a number of embodiments, for example, the deviceincludes a wireless charging system. Even further, in certainembodiments, the wireless charging system drives the ultraviolet lightsource. Further still, in some embodiments, the ultraviolet light sourceincludes at least one LED that emits the ultraviolet light. Even furtherstill, in some embodiments, the device further includes a safetymechanism, for example, that protects the user, for instance, from eyedamage from the ultraviolet light source. Still further, in someembodiments, the device for whitening teeth includes an enclosure. In anumber of embodiments, for example, the mouth piece is charged while themouth piece is in the enclosure, while the ultraviolet light source islocated in the enclosure, or both. Further, in some embodiments, theultraviolet light source turns on only while the mouth piece is in theenclosure, the ultraviolet light source turns on only while theenclosure is closed, or both. Further still, in particular embodiments,the device for whitening teeth includes at least one Hall-effect sensor,for example, that controls whether the ultraviolet light source is on.

Various specific embodiments of a device for whitening teeth include amouth piece and a sterilizer, for example, that sterilizes the mouthpiece. In a number of embodiments, for example, the sterilizersterilizes the mouth piece when the mouth piece is charging. Further, inmany embodiments, the sterilizer operates only when the mouth piece isnot in the user's mouth. Still further, in some embodiments, the deviceincludes a safety mechanism, to protect the user, for instance, from thesterilizer. Even further, in various embodiments, the device forwhitening teeth includes an enclosure that has a cover and the mouthpiece is charged while the mouth piece is in the enclosure, the mouthpiece is sterilized while the mouth piece is in the enclosure, or both.Further specific embodiments include various devices for whitening teeththat include at least one Hall-effect sensor. In a number ofembodiments, for example, the device for whitening teeth includes amouth piece and a charger. Still further, in various embodiments, theHall-effect sensor detects whether the mouth piece is docked within thecharger.

Moreover, some specific embodiments are or include a device forwhitening teeth in a mouth of a user, where the device includes at leastone sensor, for example, that senses whether the device is in the mouthof the user. In various embodiments, for example, the at least onesensor enables operation of the device only when the device is in themouth of the user, the device includes a light and the operation of thedevice includes shining the light, the at least one sensor turns on thedevice when the device is placed in the mouth of the user, the at leastone sensor includes an electro-magnetic field (EMF) array, or acombination thereof. Further, in some embodiments, the device includes atimer, for instance, that turns off the device after a certain amount oftime, for example, that the device has been operating in the mouth ofthe user. Still further, in particular embodiments, the certain amountof time is adjustable, the certain amount of time is automaticallyadjusted (e.g., by the device), the certain amount of time is adjusted(e.g., by the device, for instance, automatically) based on color orshade of the teeth, or a combination thereof, as examples. Even further,in particular embodiments, the at least one sensor includes multiplesensors, for example, at multiple points on the device. Even furtherstill, certain embodiments include a wakeup device, an accelerometer, orboth (e.g., an accelerometer that serves as a wakeup device).

Further, various specific embodiments are or include a device forwhitening teeth in a mouth of a user in which the device includes anelectro-magnetic field (EMF) array. In some embodiments, for example,the electro-magnetic field (EMF) array senses whether the device is inthe mouth of the user. Still further, in particular embodiments, theelectro-magnetic field (EMF) array turns on the device when the deviceis placed in the mouth of the user, the electro-magnetic field (EMF)array turns off the device when the device is removed from the mouth ofthe user, the electro-magnetic field (EMF) array does not allow thedevice to operate when the device is not in the mouth of the user, or acombination thereof, as examples. Even further, some specificembodiments are or include a device for whitening teeth in a mouth of auser in which the device includes an accelerometer. For example, inparticular embodiments, the accelerometer wakes up the device, forinstance, when the device is shaken.

Still further specific embodiments are or include a device for whiteningteeth of a user where the device outputs data. For example, in variousembodiments, the device includes at least one sensor that collects thedata for output from the device. Further, in a number of embodiments,the at least one sensor collects the data, the device whitens the teethof the user (e.g., by shining light on the teeth of the user), or both,for instance, while at least part of the device is in the mouth of theuser. Further still, in some embodiments, the device outputs the datawirelessly, for example, with Bluetooth. Even further, in variousembodiments, the device outputs the data to a smart device, the deviceoutputs the data to the Internet, the device outputs the data forcomputer analysis, or a combination thereof, as examples. Even furtherstill, in particular embodiments, the data is processed with machinelearning, the machine learning determines a duration for whitening theteeth, the machine learning determines an intensity for whitening theteeth, or a combination thereof, as examples. Still further, in a numberof embodiments, the data includes a shade of the teeth, the dataincludes a color of the teeth, the data from the device is compared todata from other users to automatically determine a teeth-whiteningtreatment procedure for the user, or a combination thereof, as examples.Even further still, in certain embodiments, the device notifies the userof potential health risks associated with the teeth of the user, thedevice notifies the user of potential health risks associated with gumsof the user, or both. Even further specific embodiments of a device forwhitening teeth include at least one sensor and the device is controlledby a user using hand gestures detected by the at least one sensor. Stillfurther specific embodiments of a device for whitening teeth includewireless charging in particular. Further, other embodiments aredescribed herein.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings provided herewith illustrate, among other things, examplesof certain aspects of particular embodiments. Other embodiments maydiffer. Various embodiments may include aspects shown in the drawings,described in the specification (including the claims), known in the art,or a combination thereof, as examples.

FIG. 1 is a front perspective view of an example of an embodiment of adevice or mouth piece for whitening teeth;

FIG. 2 is a rear perspective view of the example of an embodiment of adevice or mouth piece for whitening teeth of FIG. 1, showing the sidethat faces, or extends into, the user's mouth;

FIG. 3 is an exploded front view of the example of an embodiment of adevice or mouth piece for whitening teeth, of FIGS. 1 and 2;

FIG. 4 is an exploded rear view of the example of an embodiment of adevice or mouth piece for whitening teeth of FIGS. 1, 2, and 3;

FIG. 5 is an isometric rear view of an example of an embodiment of acharging enclosure for the device or mouth piece for whitening teeth ofFIGS. 1 to 4, shown with the cover closed;

FIG. 6 is an isometric front view of the example of an embodiment of acharging, enclosure of FIG. 5 for the device or mouth piece forwhitening teeth of FIGS. 1 to 4, shown with the cover open and the mouthpiece docked in the enclosure;

FIG. 7 is an exploded front view of the example of an embodiment of acharging enclosure of FIGS. 5 and 6 for the device or mouth piece forwhitening teeth of FIGS. 1 to 4, shown with the cover in the openposition and showing the mouth piece; and

FIG. 8 is a schematic or block diagram showing how different electroniccomponents are connected to each other in certain embodiments.

DETAILED DESCRIPTION OF EXAMPLES OF EMBODIMENTS

This patent application describes, among other things, examples ofcertain embodiments, and certain aspects thereof. Other embodiments maydiffer from the particular examples described in detail herein. Variousembodiments are or include devices, apparatuses, machines, and methodsfor whitening teeth. In various embodiments, for example, light is usedto whiten teeth. In many embodiments, a chemical is (e.g., also) used towhiten the teeth. In a number of embodiments, the light, or heat fromthe light, accelerates the whitening gel, for example, inside a closedsystem or mouth piece. Further various embodiments result in faster,more efficient, or longer lasting whitening, or a combination thereof,for instance, without the sensitivity of certain alternatives. Severalexamples are described herein, and different embodiments include one ormore features from one or more of the examples described herein. Allworkable combinations are contemplated as different embodiments.

FIGS. 1 to 4 illustrate an example of an embodiment of a device or mouthpiece for whitening teeth, device or mouth piece 100. In thisembodiment, device 100 includes hand gesture control or sensor 105(e.g., shown in FIG. 1) and LEDs 210 (e.g., shown in FIG. 2). In thisembodiment, LEDs (light emitting diodes) 210 collectively form a lightsource that is located outside of the user's mouth when device 100 isproperly positioned for operation, which is partially within the user'smouth. Light from LEDs 210 reflects off of polished surface or reflector220 (e.g., shown in FIG. 2) to the user's teeth when device 100 is inoperation.

In some embodiments, LEDs (e.g., 210) emit blue light. In certainembodiments, for example, the blue light has a wavelength ofapproximately 470 nm (nanometers) and is part of the “visible lightspectrum”, which ranges from approximately 400 nm to 700 nm. In variousembodiments, the light (e.g., from LEDs 210) is harmless or has no knownnegative effect to the human body. Further, particular embodiments allowthe customer or user to use the device (e.g., 100) or method forless-lengthy whitening sessions compared to other systems. Even further,in various embodiments, the serum formula works in conjunction with thelight (e.g., from LEDs 210) to speed up whitening. Further still, insome embodiments, serum is refrigerated, for example, until delivered tocustomers, for instance, in warehouse facilities. This maintains thepotency of the chemical compounds in various embodiments.

As shown in FIGS. 3 and 4, in the embodiment illustrated, device ormouth piece 100 includes decorative front cover 401, decorative chromeband 402, wireless charging receiver PCB 403, motion detection lens 404,outer case 405, battery 406, LED sensors controls 407, gesturerecognition and BLE PCB 408, self-cleaning UV LEDs and RGBW sensors 409,main hub 410 (e.g., that supports the PCBs), activating LEDs 210, LEDreflector 220, clear LED water proof cover 411, and clear silicone mouthpiece 412. Clear silicone mouth piece 412 is shown in FIG. 1 but omittedin FIG. 2 to better illustrate other components.

Activating Light Reflector

Summary of Problem:

Prior designs of activating, elements require a flexible PCB and lightelements within the mouth cavity. These source elements were fixed withno modulation schemes or intensity controls. In various embodiments,light (e.g., from LEDs 210 shown in FIGS. 2 to 4) is used to whitenteeth (e.g., in conjunction with chemical treatment). In a number ofembodiments, however, it is necessary or beneficial to avoid using toomuch light.

Solution:

In a number of embodiments, a light reflection system (e.g., LEDs 210and reflector 220) is controlled, for instance, via a pulse widthmodulation circuit (e.g., 808 shown in FIG. 8), for example, to controlthe grid and reflection pattern of a reflected light source (e.g., 210or 210 and 220). In some embodiments, light reflection patterns aredesigned to change the intensity of the light waveform, for instance, bymodifications to the peak output. Further, in particular embodiments,control mechanisms are done via wireless controls (e.g., Bluetooth),hand gestures (e.g., EMF—Electro-Magnetic Fields, IRF—Infrared Fields),or both. Still further, in certain embodiments, modulation schemes allowfor power schemes of 0-100%, for example An example of a device isdevice 100 shown in FIGS. 1 to 4, for instance. FIG. 8 is a schematic orblock diagram showing how different electronic components are connectedto each other in certain embodiments. Other embodiments may differ. Notnecessarily every electrical connection or component is shown.

In various embodiments, the components of a reflector (e.g., 220)include a (e.g., chromed) reflective surface, for example, with anangled edge, for instance, to reflect light (e.g., from one or moreLEDs, for instance, 210). Further, some embodiments, for example,include a reflector PCB, for example, that reflects light to (e.g., eachof), for instance, six (6) quadrants of teeth. These quadrants may be,for example, in some embodiments: Center Top, Center Bottom, Left Top,Left Bottom, Right Top, and Right Bottom. In certain embodiments, the(e.g., LED) reflector PCB includes or consists of 6 arrays (e.g., ofLEDs, for instance, 210), for example, independently controlled, forinstance, to light each of the 6 quadrants. In turn, in someembodiments, the arrays or LEDs (e.g., 210) are driven, for example, byPWM (Pulse Width Modulation, e.g., 808), for instance, to alter theindividual light intensity (e.g., in each quadrant). Further, inparticular embodiments, the reflector (e.g., 220) is placed over a(e.g., flex) PCB.

In various embodiments, the reflector (e.g., 220) is made out ofpolished steel, chrome plating, or polished brass, as examples. Further,in a number of embodiments, the reflector (e.g., 220) is designed (e.g.,shaped) to reflect light from outside of the users mouth (e.g., fromLEDs 210), for example, evenly, for instance, throughout the center,left, and right sides of the user's mouth. In various embodiments, thelight source (e.g., 210) is external to the mouth (i.e., when mouthpiece 100 is properly positioned for treatment of the user's teeth) andthe reflector (e.g., 220) reflects and distributes the light within themouth. In a number of embodiments, this provides controlled distributionof the light, for example, in contrast with certain prior alternativesthat do not guide the light at all.

In a number of embodiments, the light source (e.g., 210) is or includesLEDs, for example, discrete, RGB (red, green, blue), or both, forinstance, which allows for variation in the frequency of the light insome embodiments. Further, an example of the pulse width modulationcircuit is shown in FIG. 8 (e.g., 808 or TLC59108, for instance,connected to the LED arrays, for example, 210). In contrast with pulsewidth modulation (e.g., 808), other alternatives are On/Off. In a numberof embodiments, the pulse width modulation circuit (e.g., 808) controlsthe grid and reflection pattern of the reflected light source (e.g.,210). In certain embodiments, for example, the PWM circuit (e.g., 808)works with the on-board intelligence of the mouth piece (e.g., 100).When the teeth are scanned, in some embodiments, an algorithm determines(e.g., based on the timer and shade value received for the quadrant),what duty cycle to set (e.g., for each quadrant), for instance, when thetreatment begins. Due to the flexibility of the modulation scheme, inparticular embodiments, the algorithm may be further tuned, for example,to generate modulation patterns to further enhance the treatmentprocess, for instance, by the dynamic variation of the duty cycles foreach quadrant. In certain embodiments, peak output (e.g., in terms ofmillicandela or mcd), or the intensity of light (e.g., from 210) ordynamic variations is controlled, for example, by the algorithm, drivenby the PWM (e.g., 808), or both.

Further, in a number of embodiments, wireless control serves as amechanism to utilize a third-party wireless device, for example, forsetup, control, additional algorithms for analysis and treatment, or acombination thereof. Still further, in some embodiments, hand gesturesare detected (e.g., via sensor 105) via electro-magnetic field (EMF) orinfrared (IR), for instance, array 805 shown in FIG. 8), as examples.With an EMF solution, for instance, multiple antennas are set up in anarray (e.g., sensor 105), in some embodiments, generating a field whichcan be manipulated by passing through the field with a hand or finger.In a number of embodiments, the antenna field is measured by thetransmitter, and when a change is detected, the logic analyzes thecondition. In various embodiments, for instance, the order of statechanges determines the gesture to be achieved. For example: in a twoantenna system (e.g., of sensor 105), if the left antenna triggered astate change, followed by the right antenna, the logic would assume thatsomeone was swiping from left to right. Further, in certain embodiments,an IR solution works (e.g., in a similar way) using an array of IRtransmitters (e.g., of sensor 105, for example, 805), for example, withan IR receiver centrally located within the array (e.g., 105 or 805).The example above also holds true for the IR solution (e.g., 805) insome embodiments. In a number of embodiments, hand gestures are read ordetected by or at a mouth piece (e.g., 100, for instance, via sensor105). Further, certain embodiments provide a simplified way to interactwith a smart connected device. In particular embodiments, however, useof an app is avoided.

Various embodiments are or include a device (e.g., 100) for whiteningteeth. Further, different embodiments include a light reflection system(e.g., light source 210 and reflector 220), a pulse width modulationcircuit (e.g., 808 shown in FIG. 8), or both. Still further, inparticular embodiments, the lighting system (e.g., 210) or lightreflection system (e.g., 210 and 220) is controlled, for example, by thepulse width modulation circuit (e.g., 808). Even further, variousembodiments include a reflected light source (e.g., 210 or 210 and 220).Moreover, in some embodiments, the pulse width modulation circuit (e.g.,808) controls a grid, a reflection pattern of the reflected lightsource, or both. Further still, in some embodiments, light reflectionpatterns are controlled, for instance, to change intensity of a lightwaveform, for example, by modifications to a peak output.

In various embodiments, a device (e.g., 100) for whitening teeth of auser includes a light source (e.g., 210) and a light delivery mechanism(e.g., reflector 220), for example, that delivers light from the lightsource (e.g., 210) to the user's teeth. In some such embodiments, forinstance, the light source (e.g., 210) is driven by a pulse widthmodulation circuit (e.g., 808 shown in FIG. 8). Further, in a number ofembodiments, the device (e.g., 100) includes a light source (e.g., 210)and a pulse width modulation circuit (e.g., 808) that drives the lightsource (e.g., 210). Still further, in various embodiments, the lightsource (e.g., 210) is located outside the user's mouth, the mechanism(e.g., reflector 220) that delivers light from the light source (e.g.,210) to the user's teeth is located within the user's mouth (i.e., whenthe device, e.g., 100, is in use), or both. Further still, in variousembodiments, the mechanism that delivers light from the light source(e.g., 210) to the user's teeth is a reflector (e.g., 220), the lightsource includes LED's (e.g., 210), or both. Even further, in particularembodiments, the light source (e.g., 210) includes multiple (e.g.,arrays of) light sources (e.g., 210), the multiple (e.g., arrays of)light sources are each independently controlled, the multiple (e.g.,arrays of) light sources (e.g., 210) are each driven by pulse widthmodulation (e.g., 808), or a combination thereof, for example. Evenfurther still, in some embodiments, the multiple (e.g., arrays of) lightsources (e.g., 210) each primarily illuminate a different quadrant ofthe user's mouth, intensity of the multiple (e.g., arrays of) lightsources (e.g., 210) is controlled, intensity of the light source (e.g.,210) is controlled (e.g., via PWM 808), or a combination thereof, asexamples.

In a number of embodiments, the light source (e.g., 210) illuminatesvarious (e.g., six) quadrants of the user's teeth. Further, in someembodiments, the light delivery mechanism (e.g., reflector 220) deliverslight (e.g., from the light source, for instance, 210) to (e.g., six)quadrants of the user's teeth. For example, in particular embodiments,the (e.g., six) quadrants of the user's teeth are or include: CenterTop, Center Bottom, Left Top, Left Bottom, Right Top, Right Bottom, or acombination thereof, as examples. Still further, in particularembodiments, the light delivery mechanism (e.g., 220) has an anglededge. Further still, in some embodiments, the device (e.g., 100) forwhitening teeth further includes a printed circuit board. Even further,in certain embodiments, the light delivery mechanism (e.g., 220) islocated over the printed circuit board, the printed circuit board isflexible, or both. Even further still, in particular embodiments, thelight delivery mechanism (e.g., 220) delivers light (e.g., substantiallyevenly) from the light source (e.g., 210) to the user's teeth. In thiscontext, “substantially” means to within plus or minus 25 percent.

In some embodiments, the light source (e.g., 210) is an RGB lightsource. Further, in some embodiments, the device (e.g., 100) iscontrolled wirelessly, for example, using a separate electronic device.For instance, in certain embodiments, the light source (e.g., 210), inparticular, is controlled wirelessly using a separate electronic device.Still further, in some embodiments, the device (e.g., 100) is controlledusing hand gestures (e.g., via sensor 105 shown in FIG. 1). Forinstance, in particular embodiments, the light source (e.g., 210) iscontrolled using hand gestures (e.g., detected by sensor 105). Evenfurther, in some embodiments, the device (e.g., 100) includes a gesturesensor (e.g., 105), for example, for sensing the hand gestures. Furtherstill, in certain embodiments, the device (e.g., 100) or gesture sensor(e.g., 105) includes two antennas, an infrared receiver (e.g., 805), orboth.

In various embodiments of a device (e.g., 100) for whitening teeth of auser, the device includes a light source (e.g., 210) and a reflector(e.g., 220), the device includes a light source (e.g., 210) and a pulsewidth modulation circuit (e.g., 808 shown in FIG. 8), or both. Further,in various embodiments of a device (e.g., 100) for whitening teeth of auser, the device includes a light source (e.g., 210) and the lightsource is located outside the user's mouth (i.e., when the device isbeing used to whiten the teeth). Still further, in some embodiments, thedevice (e.g., 100) includes a light source (e.g., 210) that includesmultiple (e.g., arrays of) light sources (e.g., 210) and the multiple(e.g., arrays of) light sources are each independently controlled.Further still, in various embodiments, a device (e.g., 100) forwhitening teeth of a user is controlled wirelessly, for example, using aseparate electronic device. For instance, in particular embodiments, thedevice (e.g., 100) includes a light source (e.g., 210) and the device iscontrolled wirelessly (e.g., using a separate electronic device). Forexample, in some embodiments, the light source (e.g., 210) is controlledwirelessly using a separate electronic device. Even further, in certainembodiments, a device (e.g., 100) for whitening teeth of a user iscontrolled using hand gestures (e.g., via sensor 105). For example, insome embodiments, the device (e.g., 100) includes a light source (e.g.,210) that is controlled using the hand gestures (e.g., via sensor 105).Even further still, in various embodiments, a device (e.g., 100) forwhitening teeth of a user includes a light source (e.g., 210) and agesture sensor (e.g., 105 shown in FIG. 1) for sensing hand gestures,the device (e.g., 100) includes two antennas, the device (e.g., 100)includes a gesture sensor (e.g., 105) that includes two antennas, thedevice (e.g., 100) includes a light source (e.g., 210) and a gesturesensor (e.g., 105) that includes two antennas, the device (e.g., 100)includes a light source (e.g., 210) and two antennas, or a combinationthereof. Moreover, in some embodiments, a device (e.g., 100) forwhitening teeth of a user includes; an infrared receiver, a gesturesensor (e.g., 105, for instance, that includes an infrared receiver), alight source (e.g., 210) and a gesture sensor (e.g., 105, for example,that includes an infrared receiver), a light source (e.g., 210) and aninfrared receiver, or a combination thereof.

Visible Light Shade Detection System

Summary of Problem:

Until now, the accuracy of determining the color or shade of a user'steeth has been a manual process, using both personal observation andshade guides provided by the dental community.

Solution:

In various embodiments, the process of identifying the color or shade ofteeth is automated. Further, in a number of embodiments, accuracy isimproved over previous subjective methods in which color or shade was amatter of perspective. Still further, in various embodiments, (e.g.,high accuracy) color sensors (e.g., 230 shown in FIG. 2) are used. Insome embodiments, for example, these color sensors (e.g., 230) utilizered, green, blue, and white (RGBW) detection elements, as examples. Someembodiments are calibrated by using warm and cool colored white lightsources, for instance (e.g., LEDs 210 shown in FIG. 2). In variousembodiments, the sensors (e.g., 230) sense or analyze the reflectedlight from the target surface. In some embodiments, for example, thesensors (e.g., 230) sense color, while in other embodiments, the sensors(e.g., 230) sense shade, and in certain embodiments, the sensors (e.g.,230) sense both color and shade (e.g., of the teeth). Further, incertain embodiments, color or shade readings are output, for instance,over i2c, for example, in the value which references the visible lightspectrum (390-700 nm). In a number of embodiments, the data is injectedinto a learning algorithm, for instance, running on a Host processor.Still further. In particular embodiments, this Host processor, forexample, calculates the recommended treatment. Treatment settings forthe Activating element are automatically populated, in some embodiments,for instance, when the device (e.g., 100) is in autonomous mode. Evenfurther, in certain embodiments, the data is, output wirelessly (e.g.,via Bluetooth), for example, connecting to an App, to the cloud (e.g.,for detailed analysis), or both.

In various embodiments, calibration cool and warm light source elements(e.g., LEDs 210 shown in FIG. 2) are used in the calibration of the(e.g., color) sensor (e.g., 230). In some embodiments, for example, thewarm and cool elements represent the color temperature of white light inthe frequency spectrum necessary to achieve an accurate measurement ofcolor. In particular embodiments, six (e.g., color) sensors (e.g., 230)are used, for example, in the locations shown. In some embodiments, RGBWsensors are used. Further, in some embodiments, six sensors (e.g., 230)translate to six individual grids, for example, three on top and threeon the bottom. In certain embodiments, for instance, the configurationis designed to assign multiple quadrants to the mouth for analysis. Invarious embodiments, for example, the more sensors (e.g., 230), the moreaccurate the measurements will become, for instance, within eachquadrant. In various embodiments, color data is collected from the teethand used to control a teeth-whitening process, for instance, using acomputer or a processor to analyze the color data. Further, particularembodiments use a computer or a processor to analyze the color data andcontrol a teeth-whitening process (e.g., using the output from thecomputer or processor). Even further, in a number of embodiments, the“reflected light” is light originating from the teeth-whitening device(e.g., 100, for instance, from LEDs 210).

Certain embodiments use a learning algorithm to analyze color data, forexample, to determine a treatment process. In a number of embodiments,for example, a recommended treatment includes, for example, anintensity, a duration, or both (e.g., of light emitted from LEDs 210).In various embodiments, the recommended treatment is different fordifferent teeth. In various embodiments, the recommended treatment iscalculated or determined, for example, based on compiled user data.Further, in some embodiments, a learning algorithm is used, for example,to allow the user to be hands off, let the hardware control thetreatments, or both. Other embodiments, however, do not use a learningalgorithm. Still further, different embodiments, use wireless or wiredcontrol, for example, of the hardware mechanisms.

Particular embodiments include, for example, sensor initialization,calibration, measurement, and data output. In some embodiments, analgorithm receives data output, calculates color, compares color to allquadrants, sets timer and peak intensity to each quadrant (e.g., basedon shade color and delta between quadrants), or a combination thereof.In some embodiments, for example, data is output from the sensors (e.g.,230) over i2c to the host processor. Further, in some embodiments, datais input into the learning algorithm over I2c, for example, from sensors(e.g., 230), the cloud, and a smart device, for instance, running anapplication. Still further, in particular embodiments, sensor data anduser data (e.g., from the cloud) is input into the learning algorithm.Examples include, in some embodiments, shade, color, serum strength,number of treatments per day, or a combination thereof. Even further, insome embodiments, feedback that is input into the learning algorithm toenable it to learn includes treatment times (e.g., in minutes),intensity, number of uses, shade data (e.g., at start of use to end ofuse), or a combination thereof. Even further still, in particularembodiments, output that is received from the learning algorithmincludes device settings for treatment cycles, for example, intensity,duration, notifications (e.g., in the app), or a combination thereof.Moreover, in certain embodiments, output is used for treatments,enhancing the algorithm, or both. In various embodiments, treatmentsettings are or include intensity, duration, or both (e.g., of eachquadrant).

Certain embodiments include a host processor, for example, a Master i2Ccontroller for peripherals. Further, particular embodiments include anactivating element, for example, blue LEDs (e.g., 210). Further still,in some embodiments, information is automatically populated, forexample, from the hardware or from the App. Even further, someembodiments include an autonomous mode for example, that uses themachine learning, for instance, to set up the treatments. Still further,in some embodiments, other modes include gesture control, shake andwake, autonomous, wireless, or a combination thereof, as examples.

In various embodiments, a device (e.g., 100) for whitening teeth of auser includes one or more (e.g., color) sensors (e.g., 230 shown in FIG.2), for example, used to analyze reflected light from a target surfaceof the teeth, for instance, to recommend a whitening treatment for theteeth. In a number of embodiments, for example, the device (e.g., 100)produces the light (e.g., with LEDs 210) that becomes the reflectedlight when reflected by the target surface of the teeth. Further,certain embodiments are or include a device (e.g., 100) for whiteningteeth of a user that includes a (e.g., color or shade) sensor (e.g.,230), for instance, that detects color or shade of the teeth of theuser. In a number of embodiments, a device (e.g., 100) for whiteningteeth of a user detects color of the teeth of the user in particular.Still further, in various embodiments, a device (e.g., 100) forwhitening teeth of a user collects color data from the teeth andcontrols a teeth-whitening process (e.g., operation of LEDs 210) usingthe color data.

In a number of embodiments, the device includes a computer or aprocessor (e.g., local or remote, in different embodiments), forexample, that uses the (e.g., color, shade, or both) data, analyzes thedata, controls the teeth-whitening process, or a combination thereof, asexamples. In some embodiments, the device (e.g., 100) further includes alight source (e.g., 210), the device (e.g., 100) shines light on theteeth to whiten the teeth, or both. Further, in some embodiments, thedevice (e.g., including mouth piece 100) uses the color, shade, or both,of the teeth to determine how to whiten the teeth. Still further, incertain embodiments, the device uses the light reflected by the teeth todetermine how to whiten the teeth. Even further, in particularembodiments, the device (e.g., 100) emits the light (e.g., with LEDs210) that is reflected by the teeth, for instance, that is used by thedevice (e.g., including mouth piece 100) to determine how to whiten theteeth. Further still, in some embodiments, the device uses color, shade,or both, of the teeth to determine intensity of light to shine (e.g.,with LEDs 210) onto the teeth, the device (e.g., including mouth piece100) uses light reflected by the teeth to determine intensity of lightto shine (e.g., with LEDs 210) onto the teeth, or both.

In some embodiments, the device (e.g., 100) for whitening teeth of auser includes cool light source elements (e.g., LEDs 210 shown in FIG.2). Further, in some embodiments, the device (e.g., 100) includes warmlight source elements (e.g., 210). Some embodiments include both.Moreover, in various embodiments, the light source elements (e.g., 210)are used to calibrate the device (e.g., 100). Still further, in someembodiments, the device (e.g., 100) for whitening teeth of a userincludes (e.g., multiple) (e.g., color) sensors (e.g., 230). Forexample, in particular embodiments, different sensors (e.g., 230) senselight in different areas of the (e.g., user's) mouth. In certainembodiments, for instance, different (e.g., color) sensors (e.g., 230)sense light in different quadrants of the mouth. Further still, in anumber of embodiments, the device includes a processor, for example,that controls the device (e.g., 100). For instance, in some embodiments,the processor controls the intensity of light produced (e.g., with LEDs210) by the device (e.g., 100). Even further, in some embodiments, theprocessor analyzes reflected light from the teeth. For example, inparticular embodiments, the processor analyzes color, shade, or both, ofthe teeth. Even further still, in certain embodiments, the device forwhitening teeth of a user includes or uses a learning algorithm. Forexample, in some embodiments, the device uses the learning algorithm toanalyze the (e.g., color) data, to control the teeth-whitening process(e.g., light from LEDs 210), or both.

Self Cleaning Mouth Guard

Summary of Problem:

Prior designs in production offer a washable surface which leavesopportunities to grow bacteria and to cause infections within the user'smouth.

Solution:

In a number of embodiments, ultraviolet light sources, for example, areembedded within the mouth guard, for instance, to clean the mouth piecewhen the user has finished using the product. For example, FIG. 2 showsUV light source elements 240 located in device, mouth piece, or mouthguard 100. In FIG. 2, two UV light source elements 240 are visible, butin some embodiments, a third UV light source element is present oppositethe UV light source element 240 that is on the right side of FIG. 2. Insome embodiments, the UV light source elements (e.g., 240) shineultraviolet light on up to 100 percent of the mouth guard (e.g., 100) orthe portion of the surface of the mouth guard that is in the mouth ofthe user when in operation. In various embodiments, utilization of awireless charging system, and safety mechanisms to protect the usersfrom damaging their eyes during the clean cycle, require that the mouthguard (e.g., 100) be successfully docked in an enclosure and theenclosure cover closed. FIG. 5 shows an example of an enclosure,enclosure 500, with cover 501 closed. In some embodiments, for example,the enclosure (e.g., 500) has a shape of a circular cylinder (e.g., asshown, for instance, cylindrical body 510), for example, with flat ends(e.g., at top and bottom) that are perpendicular or substantiallyperpendicular to a centerline of the cylinder. FIG. 5 shows excess cablestorage 502, micro USB power connection 503, and cover hinge 505. FIG. 6shows enclosure 500 with cover 501 open and mouth piece 100 dockedinside enclosure 500 (e.g., for charging, sterilization, storage, or acombination thereof). In some embodiments, the cover (e.g., 501) hasembedded charging circuits and BLE, magnetic latching, or a combinationthereof, as examples. Further, FIG. 6 shows swing out serum wand andcable storage or swing door 660 (e.g., magnetic latching). In someinstances herein, the word “device” refers to the mouth piece (e.g.,100) only, but in other instances, the word “device” may include theenclosure (e.g., 500) or charger. Further still, in certain instances,the word “device” may include a computing device, for example, that isin communication with the mouth piece (e.g., 100). Still further, thesealternatives are not necessarily exhaustive.

In a number of embodiments, when the mouth piece (e.g., 100) has beensuccessfully docked (e.g., in enclosure 500, for instance, as shown inFIG. 6), and the enclosure cover (e.g., 501) closed (e.g., as shown inFIG. 5), Hall effect sensors, for example, on two sides of theenclosure, trigger or enable the wireless charging system. This is anexample of a safety mechanism that protects the user from eye damagefrom the ultraviolet light source. Once the transmitter has beenenabled, in some embodiments, wireless charging protocol begins totransmit to the receiver, for instance, first checking for foreignobjects in the path between the mouth guard (e.g., 100) and theenclosure (e.g., 500). In certain embodiments, once no objects aredetected and the receiver has acknowledged communication, a timer on thereceiver will trigger the UV elements (e.g., 240), for instance, for aparticular time (e.g., X.xxxmS), which is a programmable timer in someembodiments. In particular embodiments, the UV elements (e.g., 240) arepowered (e.g., directly) from the receiver side bridge and receiver, forinstance, which keeps the elements (e.g., 240) from turning onaccidently.

Various embodiments (e.g., of a teeth-whitening device, for instance,100) include one or more ultraviolet light sources (e.g., 240), forexample, LEDs., for instance, to clean (e.g., sterilize) theteeth-whitening device (e.g., mouth piece, for instance, 100). Further,in various embodiments, the “ultraviolet light sources” (e.g., 240) arelocated in the wireless charging system, are driven by the wirelesscharging system, operate (e.g., sterilize or apply UV) while chargingthe (e.g., teeth-whitening) device (e.g., 100), or a combinationthereof. Still further, certain embodiments include a safety mechanism,for example, to protect users from damaging their eyes during thecleaning cycle. Even further, particular embodiments, require that themouth guard (e.g., 100) be successfully docked in an enclosure (e.g.,500) or that the enclosure cover (e.g., 501) be closed, for example,before charging the device (e.g., mouth guard 100), emitting UV (e.g.,from UV lights 240), starting the cleaning cycle, or a combinationthereof. Further still, some embodiments use one or more Hall effectsensors, for example, to trigger or enable a wireless charging system, aUV system (e.g., UV lights 240), or a sterilization or cleaning system(e.g., UV lights 240), as examples. The drawings show examples. Indifferent embodiments, various wireless charging protocols are used.

Some embodiments include a receiver, for example, an Infineon solution.Further, certain embodiments check for foreign objects in the pathbetween the mouth guard (e.g., 100) and the enclosure (e.g., 500), forexample, by detecting heat changes, current, or both. Still further, insome embodiments, the receiver acknowledges communication using Qi. Evenfurther, some embodiments include a timer, for example, that controlsthe amount of time that the UV elements (e.g., 240) or cleaning systemis operated. In certain embodiments, the timer is adjustable, forinstance, from 1-30 minutes. Even further still, in particularembodiments, the timer is set automatically, for example, using machinelearning.

Various embodiments of a device for whitening teeth include a mouthpiece (e.g., 100 shown in FIGS. 1 to 4, 6, and 7) and an ultravioletlight source (e.g., 240 shown in FIG. 2), for example, to clean themouth piece (e.g., 100), for instance, when the user has finished usingthe device (e.g., 100). In a number of embodiments, for example, themouth piece (e.g., 100) is cleaned with the ultraviolet light (e.g.,from 240) while the device (e.g., 100) is charging. Further, in someembodiments, an ultraviolet light source (e.g., 240) sterilizes themouth piece (e.g., 100). Still further, in particular embodiments, thedevice or ultraviolet light source (e.g., 240) sterilizes the mouthpiece (e.g., 100) when the mouth piece (e.g., 100) is not in the user'smouth. Further still, in a number of embodiments, the device orultraviolet light source (e.g., 240) sterilizes the mouth piece (e.g.,100) when, user has finished using the device (e.g., 100) for whiteningthe user's teeth, for example, when the mouth piece (e.g., 100) ischarging. As used herein, “sterilizes” does not necessarily meancomplete sterilization, but many embodiments significantly reduce thequantity of harmful or potentially harmful microorganisms from at leastpart of the device or mouth piece (e.g., 100).

A number of embodiments of a device for whitening teeth include a mouthpiece (e.g., 100) and a sterilizer, for example, that sterilizes themouth piece. In various embodiments, for instance, the sterilizerincludes an ultraviolet light source (e.g., 240), the sterilizersterilizes the mouth piece (e.g., 100) when the mouth piece is not inthe user's mouth, the sterilizer sterilizes the mouth piece (e.g., 100)when user has finished using the device (e.g., 100) for whitening theuser's teeth, the sterilizer sterilizes the mouth piece (e.g., 100) whenthe mouth piece (e.g., 100) is charging, or a combination thereof, asexamples. Further, in many embodiments, a device (e.g., 100) forwhitening teeth includes an ultraviolet light source (e.g., 240). Someembodiments include a mouth piece (e.g., 100) and an ultraviolet lightsource (e.g., 240), for example, combined. In a number of embodiments,for example, the ultraviolet light source (e.g., 240) sterilizes themouth piece (e.g., 100), the ultraviolet light source (e.g., 240)operates when the mouth piece (e.g., 100) is not in the user's mouth,the ultraviolet light source (e.g., 240) operates only when the mouthpiece (e.g., 100) is not in the user's mouth, the ultraviolet lightsource (e.g., 240) operates when the user has finished using the device(e.g., 100, for example, for whitening the user's teeth), theultraviolet light source (e.g., 240) operates only when the user hasfinished using the device (e.g., mouth piece 100) for whitening theuser's teeth, the ultraviolet light source (e.g., 240) operates when themouth piece (e.g., 100) is charging, the ultraviolet light source (e.g.,240) operates only when the mouth piece (e.g., 100) is charging, or acombination thereof, as examples.

In various embodiments of the device (e.g., 100) for whitening teeth,the ultraviolet light source (e.g., 240) sterilizes at least a portionof the device (e.g., 100). Further, in some embodiments, the ultravioletlight source (e.g., 240) operates when the portion of the device (e.g.,100) is not in the user's mouth. Still further, in some embodiments, theultraviolet light source (e.g., 240) operates only when the portion ofthe device (e.g., 100) is not in the user's mouth. Even further, invarious embodiments, the ultraviolet light source (e.g., 240) operateswhen the user has finished using the device (e.g., 100) for whiteningthe user's teeth, for example, only when the user has finished using thedevice (e.g., 100) for whitening the user's teeth. Further still, insome embodiments, the ultraviolet light source (e.g., 240) operates whenthe device (e.g., 100) is charging (e.g., in enclosure 500), forinstance, only when the device (e.g., 100) is charging. Even furtherstill, in various embodiments, the device (e.g., 100) for whiteningteeth includes the ultraviolet light source (e.g., 240) and theultraviolet light source includes at least one LED, for example, thatemits the ultraviolet light. Moreover, in a number of embodiments, thedevice for whitening teeth includes a wireless charging system (e.g.,enclosure 500 or therein). Furthermore, in some embodiments, theultraviolet light source (e.g., 240) is driven by the wireless chargingsystem, the ultraviolet light source is located in the wireless chargingsystem, the device (e.g., 100) includes a safety mechanism to protectthe user from damaging their eyes with the ultraviolet light source, thedevice includes a safety mechanism to protect the user from damaging,their eyes during a cleaning cycle, or a combination thereof, asexamples. In various embodiments, the device includes a safety mechanismto protect the user during a cleaning cycle, the device includes asafety mechanism to protect the user while the device is charging, thedevice includes an enclosure (e.g., 500), the enclosure includes a cover(e.g., 501), or a combination thereof, as examples.

Moreover, in a number of embodiments, the device for whitening teethincludes a mouth piece (e.g., 100) and the mouth piece (e.g., 100) ischarged while the mouth piece (e.g., 100) is in the enclosure (e.g.,500), the mouth piece (e.g., 100) is sterilized (e.g., with 240) whilethe mouth piece (e.g., 100) is in the enclosure (e.g., 500), or both.Further, in various embodiments, the device for whitening teeth includesan ultraviolet light source (e.g., 240) and the ultraviolet light sourceis located within the enclosure (e.g., 500), turns on while the mouthpiece (e.g., 100) is in the enclosure (e.g., 500), turns on only whilethe mouth piece (e.g., 100) is in the enclosure (e.g., 500), turns onwhile the mouth piece (e.g., 100) is charging, turns on only while themouth piece (e.g., 100) is charging, or a combination thereof. Invarious embodiments, for instance, the device (e.g., 100) for whiteningteeth includes an ultraviolet light source (e.g., 240) and theultraviolet light source turns on only while the enclosure (e.g., 500,for instance, cover 501) is closed. Still further, in a number ofembodiments, the device includes a mouth piece (e.g., 100) and the mouthpiece (e.g., 100) charges in the enclosure (e.g., 500) only when theenclosure (e.g., 500, for instance, cover 501) is closed, the mouthpiece (e.g., 100) charges in the enclosure (e.g., 500) only when themouth piece (e.g., 100) is successfully docked in the enclosure (e.g.,500), or both. Further still, in various embodiments, the device forwhitening teeth includes a mouth piece (e.g., 100) and an ultravioletlight source (e.g., 240) and the ultraviolet light source only operateswhen the mouth piece (e.g., 100) is successfully docked in the enclosure(e.g., 500).

Further, in various embodiments, the device for whitening teeth includesat least one Hall-effect sensor. In a number of embodiments, forexample, the at least one Hall-effect sensor is located in the enclosure(e.g., 500), the at least one Hall-effect sensor senses whether theenclosure (e.g., 500, for instance, cover 501) is closed, the at leastone Hall-effect sensor senses whether the mouth piece (e.g., 100) isdocked within the enclosure (e.g., 500), the at least one Hall-effectsensor controls whether the device (e.g., 100) charges, the at least oneHall-effect sensor controls whether the ultraviolet light source (e.g.,240) operates, the at least one Hall-effect sensor controls whether thesterilizer (e.g., 240) operates, or a combination thereof, as examples.Still further, in various embodiments, the device (e.g., 100) forwhitening teeth includes a timer, for example, that controls how longthe sterilizer (e.g., 240) operates, controls how long the ultravioletlight source (e.g., 240) operates, or both. Even further, in someembodiments, the timer is programmable.

Mouth Detection

Summary of Problem:

Prior whitening systems are required to be plugged in or turned onbefore the device has been put into the user's mouth.

Solution:

Various embodiments include one or multiple sensors or arrays thatenable the function of the device (e.g., 100) once in the user's mouth.In some embodiments, for example, an EMF (Electro-Magnetic Field) Array(e.g., EMF field sensor or array 250 shown in FIG. 2) is placed (e.g.,at three points) around the mouth guard (e.g., 100). In someembodiments, for instance, this requires the device (e.g., 100) to be inthe mouth before operation. In addition, in particular embodiments, thearray (e.g., 250) is enabled by using a wake on pick up feature, forinstance, of an accelerometer (e.g., 811 shown in FIG. 8), to wake thedevice (e.g., 100) from a deep sleep. In some embodiments, hand gestures(e.g., detected via sensor 105) or the use of the App over a wireless(e.g., Bluetooth) connection begin the treatment cycle (e.g., operationof LEDs 210).

In prior whitening systems that were required to be plugged in or turnedon before the device has been put into the user's mouth, this was asimple way to power the device, but there was no: intelligence for theuser, modes of treatment, or a real sense of travel and portability, asexamples. In some embodiments, a user can put the device (e.g., 100) inher mouth and then turn it on or plug it in, but in particularembodiments, this may impact the results. In certain embodiments, forexample, the timer starts once the activating LEDs (e.g., 20) are on. Invarious embodiments, an electro-magnetic field (EMF) array (e.g., viaEMF field sensor or array 250 shown in FIG. 2) is used or included in ateeth-whitening device, for example, to detect whether the device (e.g.,100) is in someone's mouth. Further, in particular embodiments, thearray (e.g., 250) is enabled by using a wake on pick up feature or anaccelerometer (e.g., 811) to wake the device. In certain embodiments,for example, the accelerometer (e.g., 811) goes to an interrupt pin thatcan wake up the primary processor. In some embodiments, the device(e.g., 100) goes into a deep sleep, for example, an extremely lowcurrent state, for instance, to extend battery (e.g., 406 shown in FIGS.3 and 4) life. Still further, in various embodiments, hand gestures(e.g., detected by sensor 105) are used. For example, in particularembodiments, hand gestures may include swiping (e.g., from left toright), pressing, finger twirling (e.g., like stirring coffee), or acombination thereof, as examples. Even further, in certain embodiments,wireless communication (e.g., Bluetooth) connects the device (e.g., 100)to a smart device, for example, a smart phone. In various embodiments,to begin a treatment cycle (e.g., energize LEDs 210), a user may use theApp (e.g., on the smart device), use a gesture (e.g., detected by sensor105), shake the device (e.g., mouth piece 100, accelerometer 811, orboth), or a combination thereof, as examples.

In various embodiments, a device (e.g., 100) for whitening teethincludes at least one sensor or array (e.g., EMF sensor or array 250)that enables function of the device (e.g., 100) once the device (e.g.,100) is in the user's mouth and that requires the device (e.g., 100) tobe in the mouth before operation. In a number of embodiments, forexample, at least one sensor (e.g., 250) senses whether the device(e.g., 100) is in the user's mouth, turns on the device (e.g., 100) whenthe device is placed in the user's mouth, allows the device (e.g., 100)to operate only when the device (e.g., 100) is in the user's mouth, or acombination thereof. Further, various embodiments of a device (e.g.,100) for whitening teeth includes an electro-magnetic field (EMF) array(e.g., sensor or array 250 shown in FIG. 2). In some embodiments, forinstance, the electro-magnetic field (EMF) array (e.g., 250) senseswhether the device (e.g., 100) is in the user's mouth, turns on thedevice (e.g., 100) when the device (e.g., 100) is placed in the user'smouth, or both. Still further, in various embodiments, the at least onesensor (e.g., 250) turns off the device (e.g., 100) when the device(e.g., 100) is removed from the user's mouth, does not allow the device(e.g., 100) to operate when the device (e.g., 100) is not in the user'smouth, or both. Even further, in a number of embodiments, the device(e.g., 100) for whitening teeth includes a timer. In some embodiments,for example, the timer turns off the device (e.g., 100) after a certainamount of time that the device (e.g., 100) has been operating in theuser's mouth. Further still, in particular embodiments, the certainamount of time is adjustable. Even further still, in some embodiments,the certain amount of time is automatically adjusted, for instance, bythe device. For example, in certain embodiments, the certain amount oftime is adjusted based on color (e.g., from sensors 230) of the user'steeth. Moreover, in certain embodiments, the certain amount of time isadjusted based on shade (e.g., from sensors 230) of the user's teeth.

Additionally, in various embodiments, the function or operation of thedevice (e.g., 100) includes shining a light (e.g., 210) in the user'smouth. For example, in a number of embodiments, turning on the device(e.g., 100) includes turning on a light (e.g., 210) in the user's mouth.Further, in various embodiments of a device (e.g., 100) for whiteningteeth that has a light (e.g., 210), the light includes at least one LED.Still further, in various embodiments of a device (e.g., 100) forwhitening teeth that includes at least one sensor (e.g., 250), the atleast one sensor (e.g., 250) senses at multiple points on the device.For instance, in some embodiments, the at least one sensor (e.g., 250)includes multiple sensors at multiple points on the device (e.g., 100).For example, in particular embodiments, the at least one sensor (e.g.,250) senses at three separate points on the device (e.g., 100). Evenfurther, in some embodiments, the at least one sensor (e.g., 250) sensesat at-least three separate points on the device (e.g., 100). Furtherstill, in certain embodiments, that include at least one sensor (e.g.,250), the at least one sensor (e.g., 250) is or includes an array. Forinstance, in particular embodiments that include an array (e.g., 250),the array (e.g., 250) is used to detect whether the device (e.g., 100)is in a user's mouth. Even further still, in certain embodiments thatinclude an array, the array is an electro-magnetic field (EMF) array(e.g., via EMF field sensor or array 250 shown in FIG. 2).

In a number of embodiments of a device for whitening teeth, the device(e.g., 100) operates in a deep sleep, for example, before being turnedon, before being placed in the user's mouth, or both. Further, certainembodiments include a wakeup device (e.g., 811). Moreover, someembodiments of a device (e.g., 100) for whitening teeth include anaccelerometer (e.g., 811). In some embodiments, for example, theaccelerometer (e.g., 811) wakes up the device (e.g., 100). Stillfurther, various embodiments of a device for whitening teeth include aprocessor. Further still, in certain embodiments, the wakeup device oraccelerometer (e.g., 811) is connected to an interrupt pin on theprocessor of the device. Even further, in some embodiments, the device(e.g., 100) for whitening teeth is controlled with hand gestures (e.g.,detected by sensor 105), though a wireless connection to a smart device,or though Bluetooth (e.g., by a smart device), as examples. In variousembodiments, a device (e.g., 100) for whitening teeth is controlled witha smart device. Even further still, in some embodiments, the device(e.g., 100) for whitening teeth is controlled by shaking the device(e.g., detected by accelerometer 811). For example, in some embodiments,the device (e.g., 100) is woken up by shaking the device (e.g., 100).Furthermore, in particular embodiments, a treatment cycle is started byshaking (e.g., detected by accelerometer 811) the device (e.g., 100), bymaking a hand gesture (e.g., detected by sensor 105), with a smartdevice, by a combination of these, or by any of a combination of these,for example, selected by the user.

Wireless Dental Whitening System

Summary of Problem:

Prior whitening systems do not take advantage of machine learning or auser's specific needs.

Solution:

In a number of embodiments, a wireless connected system includes one ormultiple sensor arrays (e.g., 230), for example, that output data (e.g.,over Bluetooth) to a smart device, and, in some embodiments, (e.g.,finally) to the cloud, for instance, for analysis. In particularembodiments, the device (e.g., also) has one or more (e.g., embedded)machine learning algorithms, for example, using both a primary andsecondary host processors. Additional Flash memory, in particularembodiments, allows for storage and computation methods for treatmentand user recommendations. Further, in particular embodiments, the systemis (e.g., also) user customizable, for example, using an iOS or Androidapp, for instance, to set a manual treatment, review scan results,recommended treatments, treatment schedules, naming the device, RGBesthetic customizable LEDs, or a combination thereof. Still further, inparticular embodiments, (e.g., multiple) safety features are alsoincluded, for example, with the self-cleaning feature (e.g., 240), forinstance, to ensure that the device (e.g., 100) is (e.g., adequately)free from bacteria when properly stored. Even further, in particularembodiments, (e.g., multiple) inputs (e.g., 105) to the mouth guard(e.g., 100) allow users (e.g., that are less tech savvy) to utilize(e.g., simple) hand gestures to operate the device (e.g., 100), forexample, using infrared (e.g., 805) and/or electromagnetic fieldarray(s).

Various embodiments address user's specific needs that prior whiteningsystems do not necessarily address. Further, a number of embodimentstake advantage of technology that prior whitening systems do notnecessarily take advantage of. For example, various embodiments includewireless charging (e.g., in enclosure 500), treatments that users cantrack, machine learning (e.g., that helps improve performance),self-cleaning (e.g., using UV elements 240), shade detection (e.g., withsensors 230), wireless control, connection to the cloud, or acombination thereof. Further, in a number of embodiments, ateeth-whitening device (e.g., 100) is Internet connected. Still further,in some embodiments, a teeth-whitening device (e.g., 100) outputs data(e.g., via Bluetooth), for example, to a smart device, for (e.g.,computer) analysis, to the cloud (e.g., cloud services, for machinelearning and analysis, for notification of users of potential healthrisks, for instance, with their teeth and/or gums), or a combinationthereof, as examples.

In different embodiments, various types of sensor arrays are used.Examples of sensors include electro-magnetic field sensors (e.g., 250),infrared sensors (e.g., 805), color or shade sensors (e.g., 230), andhydrogen sulfide sensors (H2S). Further, different types of smartdevices that can be used include phones, iPods, tablets, watches, andTVs. Still further, in some embodiments, machine learning algorithms areused. In particular embodiments, for example, data from the mouth piece(e.g., 100) is uploaded to the cloud and compared to other users,progress, and settings. Further still, in certain embodiments, forexample, based on treatment outcomes, the device (e.g., 100) canauto-configure, for instance, for desired results. Even further, certainembodiments include primary and secondary host processors. For example,in some embodiments, the primary processor is an Arm Cortex M-4, thesecondary process is PIC MCU, or both. In various embodiments, theprimary processor is used for local methods and more-complex methods areprocessed in the cloud, for example. Even further still, in someembodiments, systems are user customizable. In particular embodiments,for example, users can set their own treatments, customize: timers,intensity, duration, or programs, or a combination thereof, forinstance, to cycle between teeth whitening and gum treatment.

In a number of embodiments, a device (e.g., 100) for whitening teethinclude at least one sensor (e.g., 105, 230, or both). Further, invarious embodiments, the device wirelessly outputs data from the atleast one sensor (e.g., 230), for example, to a smart device. Stillfurther, in some embodiments, the device (e.g., 100) wirelessly outputsdata from the at least one sensor (e.g., 230) to the cloud, forinstance, for analysis. Further still, in some embodiments, the device(e.g., 100) is controlled by a user using hand gestures, for example,detected by the at least one sensor (e.g., 105). Even further, in manyembodiments, a device (e.g., 100) for whitening teeth includes wirelesscharging (e.g., in enclosure 500), self cleaning (e.g., with UV elements240), machine learning, or a combination thereof, as examples. Evenfurther still, in certain embodiments, the machine learning determines aduration, for example, for whitening the teeth (e.g., by operating LEDs210), the machine learning determines an intensity, for instance, forwhitening the teeth, or both. Moreover, in particular embodiments, themachine learning uses shade of the teeth, the machine learning usescolor of the teeth (e.g., detected by sensors 230), or both. In variousembodiments, a device for whitening teeth includes color or shadedetection (e.g., using sensors 230).

Furthermore, in a number of embodiments, a device (e.g., 100) forwhitening teeth outputs data, outputs data wirelessly, outputs data withBluetooth, outputs data to a smart device, outputs data for computeranalysis, is connected to the Internet, is connected to the cloud,outputs data for cloud services, outputs data for machine learning, or acombination thereof, as examples. In some embodiments, for example, thedevice (e.g., 100) notifies users of potential health risks, forexample, with their teeth, with their gums, or both. Moreover, inparticular embodiments, the potential health risks are identified in thecomputer analysis. Further, in various embodiments, the at least onesensor is a sensor array, the device for whitening teeth includes: anelectromagnetic field sensor (e.g., 250), an infrared sensor (e.g.,805), a color or shade sensor (e.g., 230), a hydrogen sulfide sensor, ora combination thereof, as examples. Still further, in some embodiments,the smart device is or can be a phone, the smart device is or can be atablet computer, the smart device is or can be an iPod, the smart deviceis or can be a watch, the smart device is or can be a TV, or acombination thereof, as further examples. Further still, in variousembodiments, data from the device (e.g., 100) is compared to or analyzedwith data from other users. For example, in particular embodiments, datafrom the device (e.g., 100) is compared to data from other users toautomatically determine a treatment procedure (e.g., for the currentuser, other users, or both).

In various embodiments, the device includes a primary host processor,includes a secondary host processor, includes an Arm Cortex M-4processor, includes a PIC MCU processor, or a combination thereof, asexamples. Further, in many embodiments, users can set (e.g., select)their own treatments. For example, in particular embodiments, users canset a timer, users can set intensity of a treatment, users can setduration of a treatment, or a combination thereof. Further still, invarious embodiments, users can select a teeth-whitening treatment, userscan select a gum treatment, users can cycle between teeth-whitening andgum treatments, or a combination thereof, as examples.

Still other embodiments include various methods, for example, ofperforming functions described herein. Each method, for example,includes at least certain acts. Various embodiments include an apparatusor method of obtaining or providing an apparatus or information, forinstance, that include a novel combination of the features describedherein. Even further embodiments include at least one means foraccomplishing, at least one functional aspect described herein. Thesubject matter described herein includes various means for accomplishingthe various functions or acts described herein or that are apparent fromthe structure and acts described. Each function described herein is alsocontemplated as a means for accomplishing that function, or whereappropriate, as a step for accomplishing that function. Moreover,various embodiments include certain (e.g., combinations of) aspectsdescribed herein. All novel combinations that are feasible are potentialembodiments. Some embodiments may include a subset of elements describedherein and various embodiments include additional elements as well.

Further, various embodiments of the subject matter described hereininclude various combinations of the acts, structure, components, andfeatures described herein, shown in the drawings, described in anydocuments that are incorporated by reference herein, or that are knownin the art. Moreover, certain procedures can include acts such asmanufacturing, obtaining, or providing components that perform functionsdescribed herein or in the documents that are incorporated by reference.Further, as used herein, the word “or”, except where indicatedotherwise, does not imply that the alternatives listed are mutuallyexclusive. Even further, where alternatives are listed herein, it shouldbe understood that in some embodiments, fewer alternatives may beavailable, or in particular embodiments, just one alternative may beavailable, as examples.

What is claimed is:
 1. A device for whitening teeth in a mouth of auser, the device comprising at least one sensor that senses whether thedevice is in the mouth of the user.
 2. The device for whitening teeth ofclaim 1 wherein the at least one sensor enables operation of the deviceonly when the device is in the mouth of the user.
 3. The device forwhitening teeth of claim 2 wherein the device comprises a light and theoperation of the device comprises shining the light.
 4. The device forwhitening teeth of claim 1 wherein the at least one sensor turns on thedevice when the device is placed in the mouth of the user.
 5. The devicefor whitening teeth of claim 1 wherein the at least one sensor comprisesan electro-magnetic field (EMF) array.
 6. The device for whitening teethof claim 1 wherein the device further comprises a timer.
 7. The devicefor whitening teeth of claim 6 wherein the timer turns off the deviceafter a certain amount of time that the device has been operating in themouth of the user.
 8. The device for whitening teeth of claim 7 whereinthe certain amount of time is adjustable.
 9. The device for whiteningteeth of claim 8 wherein the certain amount of time is automaticallyadjusted by the device.
 10. The device for whitening teeth of claim 9wherein the certain amount of time is adjusted based on color or shadeof the teeth.
 11. The device for whitening teeth of claim 1 wherein theat least one sensor comprises multiple sensors at multiple points on thedevice.
 12. The device for whitening teeth of claim 1 further comprisinga wakeup device.
 13. The device for whitening teeth of claim 1 furthercomprising an accelerometer.
 14. A device for whitening teeth in a mouthof a user, the device comprising an electro-magnetic field (EMF) array.15. The device for whitening teeth of claim 14 wherein theelectro-magnetic field (EMF) array senses whether the device is in themouth of the user.
 16. The device for whitening teeth of claim 14wherein the electro-magnetic field (EMF) array turns on the device whenthe device is placed in the mouth of the user.
 17. The device forwhitening teeth of claim 14 wherein the electro-magnetic field (EMF)array turns off the device when the device is removed from the mouth ofthe user.
 18. The device for whitening teeth of claim 14 wherein theelectro-magnetic field (EMF) array does not allow the device to operatewhen the device is not in the mouth of the user.
 19. A device forwhitening teeth comprising an accelerometer.
 20. The device forwhitening teeth of claim 19 wherein the accelerometer wakes up thedevice when the device is shaken.